KR102159271B1 - Pin block socket device for connector checker - Google Patents

Abstract

The present invention relates to a pin block socket device for a connector tester with a novel structure to greatly contribute to the smoothness, continuity and reliability of test of a connector since the safe and precise fastening is guaranteed due to an automation custom function caused by movement even if a position between a module connector and a socket seating unit has undesirably subtle difference due to various causes by greatly improving a structure of a pin block socket device used for testing a defect of a connector. According to the present invention, the general socket device for a connector tester is realized by installing an elastic spring (310) at two or more places between a jig body base plate (10) and a pin block (30), forming both sides of the pin block (30) with a moving fixing hole (320) including a vertical hole unit (321) drilled vertically with a constant diameter and an inclined guide groove unit (322) opened in both directions, and fixing a moving fixing shaft (330) to the jig body base plate (10) in the moving fixing hole (320) while the moving fixing shaft (330) having a vertical shaft unit (331) and an inclined head (332) smaller than the diameter of the vertical hole unit (321) and the inclined guide groove unit (322) are in an inserted state.

Description

Pin block socket device for connector checker

The present invention significantly improves the structure of the pin block socket device used to inspect whether a connector is defective, so that the automation caused by the moving operation even though the position between the module connector and the socket seating part undesirably shows a small difference due to various causes. It relates to a pin block socket device for a connector tester with a new structure that greatly contributes to smoothness, continuity and reliability improvement of connector inspection work by ensuring safe and precise fastening at all times with customizable functions.

In general, for connectors widely used in the electric and electronic fields, an inspection process that closely checks the quality and strength of the product before shipment, and whether there is any defect such as disconnection or ground fault, is essential.

At this time, as a device for connector inspection, a pin block 30 in which a plurality of inspection pins (P) are inserted is fixed to a jig body base plate 10, and a connector (C) is attached to the upper portion of the pin block (30). A connector binding socket part 40 is formed in which a signal input part P-1 on the upper part of the test pin protrudes so that a plurality of ground grooves are formed and connected to each other by male and female, and the lower part of the pin block 30 A general configuration is that the signal output unit P-2 that outputs the input signal from the connector to the inspection control side (PC, etc.) through a wire or an inspection board protrudes.

That is, the connector (P) for test is fastened to the connector binding socket part (40) installed on the pin block (30), and the signal input part (P-1) and connector (C) of the connector side of the plurality of test pins (P) When connecting the ground grooves of the connector (C), the signal from the connector (C) is input to the signal input unit (P-1) of the connector side of the test pins (P), and then through the signal output unit (P-2) of the test pins (P) on the opposite side. Since it is transmitted to the inspection board and the inspection control side (PC, etc.), it is possible to perform a clear inspection for defects or abnormalities in the module connector C, including the energized status or connection status of the module connector C.

In addition, the pin block 20 and the connector binding socket unit 40 installed on the connector inspection jig body 10 for the purpose of connector inspection are capable of simultaneously binding a plurality of connector modules to perform the inspection process at once. In the case of installing in several places at regular intervals, the distance and position between the connector binding socket portion 40 on one side and the connector binding socket portion 40 on the other side are not uniform due to assembly accumulation tolerance or other causes. It can show a subtle difference without.

Therefore, in the conventional case, when a plurality of module connectors are simultaneously connected to and fastened to the connector binding socket portion 40 arranged at a plurality of places at a certain interval on the connector inspection jig body 10, a plurality of inspection pins ( There is a problem that the connection between the signal input unit P-1 on the connector side of the P) and the ground grooves of the connector C is not possible, or the pins are bent or damaged during forced connection.

This problem is not only smooth and adversely affects the performance of the inspection process, and since it is impossible to perform an automated continuous inspection process, it is necessary to solve the problem, such as significantly lowering productivity and having certain limitations in improving the reliability of connector inspection quality.

In order to overcome this, various connector seating guide devices, structures, and means that allow the connector to be more accurately and securely fastened to the connector binding socket unit 40 are applied in their own way, but in the past, the configuration is complicated. And there were problems such as being very inconvenient to use or not showing special effects.

For example, Public Utility Model No. 20-2014-0006390 (connector inspection jig) says, "In an inspection jig that detects a defect in the connector by inserting a connector including a plurality of connector pins, the insertion port into which the connector is inserted. A jig body having a formed jig body, an inspection pin that is provided on the jig body so as to face the connector pin, is electrically connected to the connector pin to detect a failure of the connector, and is provided on an inner wall of the jig body, and the jig body And a connector guide member guiding an insertion direction of the connector so that the connector pin and the test pin are parallel when the connector is inserted, and the connector guide member is the connector when the connector is inserted into the jig body. A spring for applying a contact pressure to the connector in a direction perpendicular to the insertion direction of the connector, further comprising a ball contacting the outer wall of the connector at an end of the connector guide member, the connector guide member being the jig body When is inserted, it is a rotating member that rotates in a direction parallel to the direction of insertion of the connector, and the rotating member is a hinge part that rotates the rotating member, and is coupled to the hinge part in a direction perpendicular to the insertion direction of the connector. It further comprises an elastic member for applying a force to be positioned, wherein the rotation member is formed of either plastic or flexible plastic, and the connector guide member is configured to be provided with at least one pair on the inner wall facing one of the inner walls of the jig body On the other hand, when the connector is inserted into the jig body of the connector inspection jig that detects the defect of the connector, it has the same effect as preventing damage to the inspection pin, preventing surface abrasion, and blocking the occurrence of gaps as it is correctly inserted without tilting Although stated,

In spite of the configuration of the connector guide member that allows the connector to be mounted correctly, if the corresponding position of the connector and the position where the connector is inserted show minute differences due to assembly accumulated tolerances or other causes, the assembly vehicle body may not be possible. There is still a problem in which process loss is inevitable because it is difficult to avoid problems such as damage to the connector or inspection pin.

Accordingly, in the present invention, when the connector C is fastened to the connector binding socket portion 40 where the connector-side signal input unit P-1 of the plurality of inspection pins P protrudes, due to assembly tolerances, etc. Even though the corresponding connector and the position of the connector binding socket portion 40 from which the test pin (P) protrudes shows a slight difference, it is found and matched by itself by the moving operation. It was completed as a technical task with the focus on providing a new connector tester pin block socket device that allows for safer and more natural automated fastening, without forceful fitting between inspection pins, including concerns such as damage.

The present invention for achieving the above technical problem is in the socket device for a conventional connector inspection, installing an elastic spring 310 at two or more places between the jig body base plate 10 and the pin block 30; Forming a moving fixing hole 320 including a vertical hole portion 321 drilled vertically with a constant diameter and an inclined guide groove portion 322 open in both directions on both sides of the pin block 30; In the moving fixing hole 320, a moving fixing shaft 330 having a vertical shaft portion 331 and an inclined head 332 smaller than the diameter of the vertical hole portion 321 and the inclined guide groove portion 322 It is fixed to the jig body base plate 10 in the inserted state.

As described above, the pin block socket device for a connector tester of the present invention moves as described above (an operation of finding a place by itself while moving elastically). Causes such as assembly tolerances when the connector is connected to the connector binding socket part 40 and then fastened. Even if the location of each other shows a slight difference, it is possible to securely automate customized fastening, so it can be clearly avoided from problems such as damage (broken) of the inspection pin or poor connection due to unreasonable forcible fitting, and more secure and precise It is a useful invention, as it greatly helps to perform continuous automated inspection process.

1 is a perspective view showing a preferred embodiment of the present invention
2 is a detailed structural diagram of an inspection pin
3 is an exploded perspective view showing a preferred embodiment of the present invention
Figure 4 is a perspective view of an extract of the pin block of the present invention
5 to 6 are cross-sectional views before and after operation showing a preferred embodiment of the present invention
7 is an exploded cross-sectional view showing a preferred embodiment of the present invention
8 is an enlarged cross-sectional view showing a main part of the present invention

The pin block socket device for a connector tester according to the present invention will be described in more detail with reference to the accompanying drawings.

That is, in the present invention, a pin block 30 in which a plurality of inspection pins (P) are inserted is installed in a fixing block 20 that can be installed two or more on the jig body base plate 10, and the pin block 30 At the upper part of the connector (C) a plurality of ground grooves and a connector binding socket portion 40 is configured in which the signal input unit (P-1) on the upper part of the test pin protrudes so that a connection is made by being inserted into each other in male and female. A general connector inspection socket device in which a signal output unit (P-2) that outputs the input connector signal to the inspection control side (PC, etc.) through a wire or inspection board is protruded under the pin block 30. In,

An elastic spring 310 is installed at two or more places between the pin block 30 and the fixed block 20 in a state where the vertical clearance space L at a constant interval is maintained to enable elastic flow. That;

On both sides of the pin block 30, a moving fixing hole 320 including a vertical hole portion 321 drilled in a predetermined diameter vertically and an inclined guide groove portion 322 opened in both directions is formed;

The moving fixing holes 320 on both sides of the pin block 30 have a vertical shaft portion 331 and an inclined head portion 332 smaller than the diameter of the vertical hole portion 321 and the inclined guide groove portion 322. The characteristic point was that the moving fixing shaft 330 was fixed to the jig body base plate 10.

If the pin block socket device for a connector tester is configured in this way, when the connector C, which is the test subject, is fastened to the connector binding socket part 40, even though the positions are not accurate and have slight differences,

In the process of fastening between the connector (C) and the connector binding socket (40), the pin block (30) including the connector binding socket (40) finds its own position according to the free movement of the left and right fine movements, and is precisely automated. Because it is possible to respond,

Of course, more secure and smooth fastening between the connector (C) and the connector binding socket (40) is guaranteed,

It is a useful invention that not only prevents various defects, including breakage of sensitive inspection pins, abrasion of connector ground grooves, or damage of each component during fastening, but also greatly aids in improving inspection quality and performing continuous automated inspection processes.

At this time, the moving fixing holes 320 and the moving fixing shaft 330 formed on both sides of the pin block 30 are, when fixing the pin block 30 to the fixing block 20, the elastic spring 310 therebetween. The upper and lower clearance spaces (L) spaced at regular intervals up and down by the elastic reaction force are secured, and at the same time, the free space part 400 having a predetermined gap between the moving fixing hole 320 and the moving fixing shaft 330 is provided. By having,

In order to bind the connector to the connector binding socket unit 40, when the connector is vertically corresponded by pushing from the top to the bottom by a connector loading means (robot, etc.), the moving operation is performed even though the positions of the connectors show minute differences. Because it is possible, it is not unreasonable, safe and precise coupling is possible.

That is, when the position of the signal input part (P-1) at the upper end of the test pin protruding from the connector binding socket part 40 is slightly shifted from the position of the connector grounding groove, the downward pushing action accompanying the connector fastening process occurs. As the positions of the socket part 40 for binding the pin block and the connector and the signal input part (P-1) at the upper end of the test pin move finely to the left and right, the signal input part (P-1) at the upper part of the test pin is automatically placed in the connector grounding groove. Since the moving operation to find and enter is made, the clear fastening and safety of the connector (C) can be extremely high.

In particular, the inclined guide groove 322 on the upper part of the moving fixing hole 320 and the inclined head 332 having the same inclination angle also on the upper part of the moving fixing shaft 330 are provided with each other when the pin block is raised upward after moving. As the guided slope guide surfaces 322a and 332a are allocated so that the automatic return to the normal center position can be made while being guided between the slopes,

When the pin block is raised after the moving operation, despite the existence of the free space part 400, which is a gap of a certain size, between the vertical hole part 321 of the moving fixing hole 320 and the vertical axis part 331 of the moving fixing shaft 330 And, as the guiding slope guide surfaces 322a and 332a are guided, automatic return to the normal center position is possible, so that preparation for the next operation and a continuous inspection process are possible.

And the moving fixed shaft 330 having the vertical shaft portion 331 and the inclined head portion 332 may be manufactured as an integral type, but the coupling bolt 341 is first configured inside and then precisely processed on the outside. If the bush 342 is assembled in a double structure, it may be effective because more effective moving functions can be performed.

In addition, the opening inclination angle of the inclined head 332 of the moving fixing shaft 330 and the guiding inclined guide surfaces 322a and 332a formed in the guide groove 322 of the moving fixing hole 320 is unreasonable for the guide action. A smooth inclination angle without suffix is sufficient, and it can be up to about 30° to 70°, but 60° is the most ideal.

In addition, if the gap of the free space portion 400 allocated between the vertical hole portion 321 of the moving fixing hole 320 and the vertical shaft portion 331 of the moving fixing shaft 330 is increased to a degree or more, the gap is unnecessary. It can be unstable because it is large, and if it is configured too small, the effect of the moving motion may not be exerted properly due to the limitation of the gap width. Therefore, it can be set to 0.1 ~ 1mm at the maximum, and 0.35mm is the most preferable among the results of the experiment. Appeared.

P: Inspection pin P-1: Signal input unit
P-2: Signal output section C: Connector
L: Top and bottom clearance 10: Jig body base plate
20: fixed block 30: pin block
40: connector binding socket 310: elastic spring 320: moving fixing hole
321: vertical hole portion 322: inclined guide groove portion
330: moving fixed shaft 331: vertical shaft loan
332: Inclined head

Claims (5)

A pin block 30 in which a plurality of inspection pins (P) are inserted is installed in a fixing block 20 that can be installed two or more on the jig body base plate 10, and a connector ( A connector binding socket portion 40 is formed in which a signal input portion (P-1) above the test pin protrudes so that a plurality of ground grooves formed in C) and the male and female are inserted into each other to be connected, and the pin block 30 In the connector tester pin block socket device in which a signal output part (P-2) for outputting the input signal of the connector to the test control side through a wire or test board is protruded below the

An elastic spring 310 is installed at two or more places between the pin block 30 and the fixed block 20 in a state where the vertical clearance space L at a constant interval is maintained to enable elastic flow. That;
On both sides of the pin block 30, a moving fixing hole 320 including a vertical hole portion 321 drilled in a predetermined diameter vertically and an inclined guide groove portion 322 opened in both directions is formed;
The moving fixing holes 320 on both sides of the pin block 30 have a vertical shaft portion 331 and an inclined head portion 332 smaller than the diameter of the vertical hole portion 321 and the inclined guide groove portion 322. A pin block socket device for a connector tester, characterized in that the moving fixing shaft 330 is fixed to the jig body base plate 10.
The method of claim 1,
In the inclined guide groove portion 322 above the moving fixing hole 320 and the inclined head portion 332 having the same inclination angle above the moving fixing shaft 330,
A pin block socket device for a connector tester, characterized in that guiding inclined guide surfaces (322a, 332a) are allocated so that the inclined surfaces are guided to each other when the pin block rises upward after the moving operation, so that automatic return to the normal center position is made.
The method of claim 2,
The opening inclination angle of the inclined head 332 of the moving fixing shaft 330 and the guiding inclined guide surfaces 322a and 332a formed in the guide groove 322 of the moving fixing hole 320 is,
Pin block socket device for a connector tester, characterized in that it can be formed in the range of 30° to 70°.
The method of claim 1,
Connector inspection, characterized in that the gap of the free space portion 400 allocated between the vertical hole portion 321 of the moving fixing hole 320 and the vertical shaft portion 331 of the moving fixing shaft 330 is 0.1 to 1 mm Pin block socket device for machine.
The method of claim 1,
The moving fixed shaft 330 having the vertical shaft portion 331 and the inclined head portion 332,
All-in-one or,
A pin block socket device for a connector tester, characterized in that it can be manufactured in a double structure in which a coupling bolt 341 is first configured inside and then a bush 342 precision-machined with a precise gap and diameter is combined on the outside.

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